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# Copyright 2001, 2002, 2003 Dave Abrahams
# Copyright 2006 Rene Rivera
# Copyright 2002, 2003 Vladimir Prus
# Distributed under the Boost Software License, Version 1.0.
# (See accompanying file LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)
import assert ;
import numbers ;
import modules ;
# Note that algorithms in this module execute largely in the caller's module
# namespace, so that local rules can be used as function objects. Also note that
# most predicates can be multi-element lists. In that case, all but the first
# element are prepended to the first argument which is passed to the rule named
# by the first element.
# Return the elements e of $(sequence) for which [ $(predicate) e ] has a
# non-null value.
#
rule filter ( predicate + : sequence * )
{
local caller = [ CALLER_MODULE ] ;
local result ;
for local e in $(sequence)
{
if [ modules.call-in $(caller) : $(predicate) $(e) ]
{
result += $(e) ;
}
}
return $(result) ;
}
# Return a new sequence consisting of [ $(function) $(e) ] for each element e of
# $(sequence).
#
rule transform ( function + : sequence * )
{
local caller = [ CALLER_MODULE ] ;
local result ;
for local e in $(sequence)
{
result += [ modules.call-in $(caller) : $(function) $(e) ] ;
}
return $(result) ;
}
if [ HAS_NATIVE_RULE sequence : transform : 1 ]
{
NATIVE_RULE sequence : transform ;
}
rule reverse ( s * )
{
local r ;
for local x in $(s)
{
r = $(x) $(r) ;
}
return $(r) ;
}
rule less ( a b )
{
if $(a) < $(b)
{
return true ;
}
}
# Insertion-sort s using the BinaryPredicate ordered.
#
rule insertion-sort ( s * : ordered * )
{
if ! $(ordered)
{
return [ SORT $(s) ] ;
}
else
{
local caller = [ CALLER_MODULE ] ;
ordered ?= sequence.less ;
local result = $(s[1]) ;
if $(ordered) = sequence.less
{
local head tail ;
for local x in $(s[2-])
{
head = ;
tail = $(result) ;
while $(tail) && ( $(tail[1]) < $(x) )
{
head += $(tail[1]) ;
tail = $(tail[2-]) ;
}
result = $(head) $(x) $(tail) ;
}
}
else
{
for local x in $(s[2-])
{
local head tail ;
tail = $(result) ;
while $(tail) && [ modules.call-in $(caller) : $(ordered) $(tail[1]) $(x) ]
{
head += $(tail[1]) ;
tail = $(tail[2-]) ;
}
result = $(head) $(x) $(tail) ;
}
}
return $(result) ;
}
}
# Merge two ordered sequences using the BinaryPredicate ordered.
#
rule merge ( s1 * : s2 * : ordered * )
{
ordered ?= sequence.less ;
local result__ ;
local caller = [ CALLER_MODULE ] ;
while $(s1) && $(s2)
{
if [ modules.call-in $(caller) : $(ordered) $(s1[1]) $(s2[1]) ]
{
result__ += $(s1[1]) ;
s1 = $(s1[2-]) ;
}
else if [ modules.call-in $(caller) : $(ordered) $(s2[1]) $(s1[1]) ]
{
result__ += $(s2[1]) ;
s2 = $(s2[2-]) ;
}
else
{
s2 = $(s2[2-]) ;
}
}
result__ += $(s1) ;
result__ += $(s2) ;
return $(result__) ;
}
# Join the elements of s into one long string. If joint is supplied, it is used
# as a separator.
#
rule join ( s * : joint ? )
{
joint ?= "" ;
return $(s:J=$(joint)) ;
}
# Find the length of any sequence.
#
rule length ( s * )
{
local result = 0 ;
for local i in $(s)
{
result = [ CALC $(result) + 1 ] ;
}
return $(result) ;
}
rule unique ( list * : stable ? )
{
local result ;
local prev ;
if $(stable)
{
for local f in $(list)
{
if ! $(f) in $(result)
{
result += $(f) ;
}
}
}
else
{
for local i in [ SORT $(list) ]
{
if $(i) != $(prev)
{
result += $(i) ;
}
prev = $(i) ;
}
}
return $(result) ;
}
# Returns the maximum number in 'elements'. Uses 'ordered' for comparisons or
# 'numbers.less' if none is provided.
#
rule max-element ( elements + : ordered ? )
{
ordered ?= numbers.less ;
local max = $(elements[1]) ;
for local e in $(elements[2-])
{
if [ $(ordered) $(max) $(e) ]
{
max = $(e) ;
}
}
return $(max) ;
}
# Returns all of 'elements' for which corresponding element in parallel list
# 'rank' is equal to the maximum value in 'rank'.
#
rule select-highest-ranked ( elements * : ranks * )
{
if $(elements)
{
local max-rank = [ max-element $(ranks) ] ;
local result ;
while $(elements)
{
if $(ranks[1]) = $(max-rank)
{
result += $(elements[1]) ;
}
elements = $(elements[2-]) ;
ranks = $(ranks[2-]) ;
}
return $(result) ;
}
}
NATIVE_RULE sequence : select-highest-ranked ;
rule __test__ ( )
{
# Use a unique module so we can test the use of local rules.
module sequence.__test__
{
import assert ;
import sequence ;
local rule is-even ( n )
{
if $(n) in 0 2 4 6 8
{
return true ;
}
}
assert.result 4 6 4 2 8 : sequence.filter is-even : 1 4 6 3 4 7 2 3 8 ;
# Test that argument binding works.
local rule is-equal-test ( x y )
{
if $(x) = $(y)
{
return true ;
}
}
assert.result 3 3 3 : sequence.filter is-equal-test 3 : 1 2 3 4 3 5 3 5 7 ;
local rule append-x ( n )
{
return $(n)x ;
}
assert.result 1x 2x 3x : sequence.transform append-x : 1 2 3 ;
local rule repeat2 ( x )
{
return $(x) $(x) ;
}
assert.result 1 1 2 2 3 3 : sequence.transform repeat2 : 1 2 3 ;
local rule test-greater ( a b )
{
if $(a) > $(b)
{
return true ;
}
}
assert.result 1 2 3 4 5 6 7 8 9 : sequence.insertion-sort 9 6 5 3 8 7 1 2 4 ;
assert.result 9 8 7 6 5 4 3 2 1 : sequence.insertion-sort 9 6 5 3 8 7 1 2 4 : test-greater ;
assert.result 1 2 3 4 5 6 : sequence.merge 1 3 5 : 2 4 6 ;
assert.result 6 5 4 3 2 1 : sequence.merge 5 3 1 : 6 4 2 : test-greater ;
assert.result 1 2 3 : sequence.merge 1 2 3 : ;
assert.result 1 : sequence.merge 1 : 1 ;
assert.result foo-bar-baz : sequence.join foo bar baz : - ;
assert.result substandard : sequence.join sub stan dard ;
assert.result 3.0.1 : sequence.join 3.0.1 : - ;
assert.result 0 : sequence.length ;
assert.result 3 : sequence.length a b c ;
assert.result 17 : sequence.length 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 ;
assert.result 1 : sequence.length a ;
assert.result 10 : sequence.length a b c d e f g h i j ;
assert.result 11 : sequence.length a b c d e f g h i j k ;
assert.result 12 : sequence.length a b c d e f g h i j k l ;
local p2 = x ;
for local i in 1 2 3 4 5 6 7 8
{
p2 = $(p2) $(p2) ;
}
assert.result 256 : sequence.length $(p2) ;
assert.result 1 2 3 4 5 : sequence.unique 1 2 3 2 4 3 3 5 5 5 ;
assert.result 5 : sequence.max-element 1 3 5 0 4 ;
assert.result e-3 h-3 : sequence.select-highest-ranked e-1 e-3 h-3 m-2 : 1 3 3 2 ;
assert.result 7 6 5 4 3 2 1 : sequence.reverse 1 2 3 4 5 6 7 ;
}
}
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